Glaser Franz T, Stanewsky Ralf
Institut für Zoologie, Universität Regensburg, 93040 Regensburg, Germany.
Curr Biol. 2005 Aug 9;15(15):1352-63. doi: 10.1016/j.cub.2005.06.056.
Circadian clocks are synchronized by both light:dark cycles and by temperature fluctuations. Although it has long been known that temperature cycles can robustly entrain Drosophila locomotor rhythms, nothing is known about the molecular mechanisms involved.
We show here that temperature cycles induce synchronized behavioral rhythms and oscillations of the clock proteins PERIOD and TIMELESS in constant light, a situation that normally leads to molecular and behavioral arrhythmicity. We show that expression of the Drosophila clock gene period can be entrained by temperature cycles in cultured body parts and isolated brains. Further, we show that the phospholipase C encoded by the norpA gene contributes to thermal entrainment, suggesting that a receptor-coupled transduction cascade signals temperature changes to the circadian clock. We initiated the further genetic dissection of temperature-entrainment and isolated the novel Drosophila mutation nocte, which is defective in molecular and behavioral entrainment by temperature cycles but synchronizes normally to light:dark cycles.
We conclude that temperature synchronization of the circadian clock is a tissue-autonomous process that is able to override the arrhythmia-inducing effects of constant light. Our data suggest that it involves a cell-autonomous signal-transduction cascade from a thermal receptor to the circadian clock. This process includes the function of phospholipase C and the product specified by the novel mutation nocte.
昼夜节律时钟通过明暗周期和温度波动来同步。尽管长期以来人们都知道温度周期能够有力地调节果蝇的运动节律,但对于其中涉及的分子机制却一无所知。
我们在此表明,在持续光照下(这种情况通常会导致分子和行为上的节律失调),温度周期会诱导时钟蛋白周期(PERIOD)和无时间(TIMELESS)的同步行为节律及振荡。我们表明,果蝇时钟基因周期的表达能够在培养的身体部位和分离的大脑中被温度周期所调节。此外,我们表明由无活性A(norpA)基因编码的磷脂酶C有助于热调节,这表明一种受体偶联的转导级联将温度变化信号传递给昼夜节律时钟。我们启动了对温度调节的进一步基因剖析,并分离出了新的果蝇突变体夜猫子(nocte),它在通过温度周期进行分子和行为调节方面存在缺陷,但能正常地与明暗周期同步。
我们得出结论,昼夜节律时钟的温度同步是一个组织自主的过程,能够克服持续光照引起的节律失调效应。我们的数据表明,它涉及从热感受器到昼夜节律时钟的细胞自主信号转导级联。这个过程包括磷脂酶C的功能以及新突变体夜猫子所指定的产物。
